JP7209186B2 - AIR CONDITIONING SYSTEM AND CONTROL METHOD OF AIR CONDITIONING SYSTEM - Google Patents

Description

The present invention relates to an air conditioning system and a control method for an air conditioning system.

Conventionally, in an air conditioning system including an outdoor unit and an indoor unit connected to the outdoor unit, a technique is known in which the indoor unit sets the capacity of the indoor unit (see, for example, Patent Document 1). Patent Literature 1 discloses a technique in which an indoor unit stores control data for a plurality of models, selects control data corresponding to model data received from a remote controller, and sets the capability of the indoor unit.

JP-A-7-103558

However, Patent Literature 1 assumes that the number of indoor units connected to an outdoor unit is one, and does not consider the setting of the capacity of the indoor units when there are a plurality of indoor units connected to the outdoor unit. Therefore, in Patent Document 1, when there are multiple indoor units connected to the outdoor unit, for example, the total capacity of the indoor units set for each indoor unit exceeds the capacity of the outdoor unit. may not be able to appropriately set the capacity of the indoor unit.
Therefore, the present invention has been made in view of the above circumstances, and an air conditioning system in which each indoor unit can set an appropriate indoor unit capacity even when a plurality of indoor units are connected to the outdoor unit, and , and an object thereof is to provide a control method for an air conditioning system.

To achieve the above objects, the present invention provides an air conditioning system comprising an outdoor unit and a plurality of indoor units connected to the outdoor unit, wherein the indoor unit comprises an indoor unit control unit and an indoor unit communication unit. wherein the indoor unit control unit receives outdoor functional capacity information indicating the capacity of the outdoor unit from the indoor unit communication unit, detects the number of the indoor units provided in the air conditioning system, and detects the detected indoor determining the capacity of the indoor unit according to the number of the detected indoor units based on the number of units and the capacity of the outdoor unit indicated by the received outdoor function capacity information, and the capacity of the determined indoor unit is characterized by setting
According to the present invention, since each indoor unit connected to the outdoor unit sets the capacity of the indoor unit according to the number of indoor units connected to the outdoor unit, a plurality of indoor units are connected to the outdoor unit. Even in such a case, each indoor unit can set an appropriate indoor unit capacity.

ADVANTAGE OF THE INVENTION According to this invention, even when several indoor units are connected with an outdoor unit, each indoor unit can set the capability of an appropriate indoor unit.

The figure which shows the structure of an air conditioning system. Schematic of an air conditioning system. The figure which shows the control structure of an outdoor unit and an indoor unit. 4 is a flowchart showing operations of an outdoor unit and an indoor unit; 4 is a sequence diagram showing the operation of the air conditioning system; FIG.

A first invention is an air conditioning system comprising an outdoor unit and a plurality of indoor units connected to the outdoor unit, wherein the indoor unit comprises an indoor unit control unit and an indoor unit communication unit, and the indoor unit The control unit receives outdoor functional capacity information indicating the capacity of the outdoor unit from the outdoor unit via the indoor unit communication unit, detects the number of the indoor units included in the air conditioning system, and detects the detected indoor unit. determining the capacity of the indoor unit according to the number of the detected indoor units based on the number of units and the capacity of the outdoor unit indicated by the received outdoor function capacity information, and the capacity of the determined indoor unit set.
According to this, since each indoor unit connected to the outdoor unit sets the capacity of the indoor unit according to the number of connections of the indoor units connected to the outdoor unit, when a plurality of indoor units are connected to the outdoor unit However, each indoor unit can set an appropriate indoor unit capacity.

In a second aspect of the invention, the indoor unit control unit divides the capacity of the outdoor unit indicated by the received outdoor function power information by the number of the detected indoor units, and the capacity of the outdoor unit obtained by dividing Based on this, the capacity of the indoor unit is determined.
According to this, each of the indoor units has the capacity of the indoor unit corresponding to the number of indoor units connected to the outdoor unit with respect to the capacity of the outdoor unit, and the capacity of the indoor unit is the same as that of the other indoor units can be set. Therefore, each indoor unit can set the capacity of the indoor unit so that the total capacity of the indoor unit set by each indoor unit is within the allowable range of the capacity of the outdoor unit.

In a third aspect of the invention, the indoor unit control section monitors whether or not all the indoor units provided in the air conditioning system have completed setting the capabilities of the indoor units for a predetermined period of time.
According to this, it is possible to prevent each indoor unit from executing other processing after setting the capacity until the setting of all the indoor units is completed for a predetermined period. Therefore, even if a time lag occurs in setting the capacity of each indoor unit, the air conditioning system can enable all the indoor units connected to the outdoor unit to set the capacity of the indoor units.

In a fourth aspect of the invention, the indoor unit includes an indoor unit storage unit that stores control data corresponding to the capabilities of the indoor unit for each of a plurality of capabilities of the indoor unit.
According to this, the indoor unit stores control data for each of a plurality of capacities of the indoor unit, so that the number of models of the indoor unit, for example, the number of capacities of the indoor unit and the number of types of housings of the indoor unit, can be calculated. It is not necessary to use a multiplied number, and only the number of different kinds of housings can be used. Therefore, an increase in the number of models of indoor units can be suppressed. In addition, since an increase in the number of models of indoor units can be suppressed, management of indoor units such as inventory management becomes easier.

In a fifth aspect of the invention, the indoor unit control section receives the outdoor functional power information from the outdoor unit through the indoor unit communication section.
According to this, even if each indoor unit receives the outdoor functional capacity information from the outdoor unit, each indoor unit can appropriately set the capacity of the indoor unit.

In a sixth aspect of the present invention, the indoor unit control unit of the one indoor unit receives the outdoor functional power information from the outdoor unit by the indoor unit communication unit, and the other indoor unit different from the one indoor unit The indoor unit control unit of the unit receives the outdoor function power information from the one indoor unit through the indoor unit communication unit.
According to this, even in a configuration in which one indoor unit receives the outdoor functional force information from the outdoor unit, and another indoor unit different from the one indoor unit receives the outdoor functional force information from the one indoor unit, each The ability of the indoor unit can be set appropriately for the indoor unit.

In a seventh invention, the outdoor unit includes an outdoor unit control unit, an outdoor unit communication unit, and a notification unit, and the outdoor unit control unit is set from all the indoor units by the outdoor unit communication unit. When the sum of the obtained indoor unit capacities is outside the allowable range of the outdoor unit capacities, the notification unit issues a warning.
According to this, the user who sets the indoor unit can recognize that the total capacity of the indoor units set for each indoor unit is outside the allowable range of the capacity of the outdoor unit. can support

An eighth aspect of the invention is a control method for an air conditioning system comprising an outdoor unit and a plurality of indoor units connected to the outdoor unit, wherein the indoor unit has an outdoor functional power indicating the capability of the outdoor unit from the outdoor unit. Information is received, the number of the indoor units included in the air conditioning system is detected, and the detected number is detected based on the number of the detected indoor units and the capacity of the outdoor unit indicated by the received outdoor functional capacity information. A capacity of the indoor unit is determined according to the number of the indoor units, and the determined capacity of the indoor unit is set.
According to this, since each indoor unit connected to the outdoor unit sets the capacity of the indoor unit according to the number of connections of the indoor units connected to the outdoor unit, when a plurality of indoor units are connected to the outdoor unit However, each indoor unit can set an appropriate indoor unit capacity.

An embodiment of an air conditioning system 1 according to the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram showing the configuration of an air conditioning system 1. As shown in FIG.

The air conditioning system 1 is a system installed in facilities such as large buildings and schools. As shown in FIG. 1, an air conditioning system 1 includes an outdoor unit 2 installed outdoors and a plurality of indoor units 3 installed indoors. The air conditioning system 1 of this embodiment has a configuration in which four indoor units 3A, 3B, 3C, and 3D are connected to one outdoor unit 2, respectively. The air conditioning system 1 performs air conditioning operation with the outdoor unit 2 and the indoor unit 3, and air-conditions the room to be conditioned in which the indoor unit 3 is installed.

The outdoor unit 2 has a compressor 20 . A gas-liquid separator 21 that supplies gas refrigerant to the compressor 20 is connected to the suction side of the compressor 20, and a four-way valve 23 is connected to the discharge side of the compressor 20 via an oil separator 22. ing. An outdoor heat exchanger 25 having an outdoor blower fan 24 is connected to the four-way valve 23 . The outdoor heat exchanger 25 is configured to exchange heat between the air sent by the outdoor fan 24 and the refrigerant.
An outdoor expansion valve 26 is connected to the outdoor heat exchanger 25 .

A plurality of indoor units 3 are connected to the outdoor expansion valve 26 and the four-way valve 23 via refrigerant pipes 27 . Each indoor unit 3 has an indoor heat exchanger 31 with an indoor blower fan 30 , and an indoor expansion valve 32 is connected to one side of the indoor heat exchanger 31 .

The outdoor unit 2 also includes an outdoor unit communication unit 201 that communicates with each indoor unit 3 via the communication network 4 . A low-pressure sensor 28 for detecting the pressure of the refrigerant flowing into the compressor 20 is provided on the refrigerant suction side of the compressor 20 of the outdoor unit 2, and the refrigerant discharged from the compressor 20 is provided on the refrigerant discharge side of the compressor 20. A high pressure sensor 29 is provided to detect the refrigerant pressure. Furthermore, the refrigerant discharge side of the compressor 20 is provided with an outdoor refrigerant temperature sensor 40 for detecting the refrigerant discharge temperature, and the outdoor unit 2 is provided with an outdoor temperature sensor 41 for detecting the outdoor temperature. .

The indoor unit 3 includes an indoor unit communication unit 301 that communicates with the outdoor unit 2 or other indoor units 3 via the communication network 4 . On both sides of the indoor heat exchanger 31 of the indoor unit 3, indoor refrigerant temperature sensors 33 are provided to detect the temperature of the refrigerant.

FIG. 2 is a schematic diagram of the air conditioning system 1. As shown in FIG.
As shown in FIG. 2 , the air conditioning system 1 includes an outdoor unit 2 and multiple indoor units 3 connected to the outdoor unit 2 . In addition, the air conditioning system 1 includes as many remote controllers 50 as the indoor units 3 .

As shown in FIG. 2, the indoor unit 3 includes a decorative panel 34. An air intake port 35 is provided in the central portion of the decorative panel 34, and the decorative panel 34 has air outlets along each side. A mouth 36 is provided. A flap 37 for adjusting the wind direction of the air is swingably provided at the outlet 36 . The indoor unit 3 is configured to drive the indoor blower fan 30 to take in indoor air from the suction port 35, and to blow the air after heat exchange with the indoor heat exchanger 31 into the room from the outlet 36. ing.

The remote controller 5 has a box-shaped main body 51 installed on a wall surface in a room. On the front surface of the main body 51, a remote control display section 52 is provided, which is composed of, for example, a liquid crystal display panel. Below the remote control display unit 52, a plurality of operation buttons 53 are provided for the user to start or stop operation, menu operation, cursor key operation, and the like. A display lamp 54 composed of, for example, an LED or the like for displaying the operating state of the indoor unit 3 is provided at the lower right portion of the front surface of the main body 51 .

Next, the control configuration of the outdoor unit 2 and the indoor unit 3 that constitute the air conditioning system 1 will be described.
FIG. 3 is a block diagram showing the control configuration of the outdoor unit 2 and the indoor unit 3. As shown in FIG.
In FIG. 3, the control configuration of the indoor unit 3 will be described as a representative of the indoor unit 3A. Each of the indoor units 3B, 3C, and 3D has the same control configuration as the control configuration of the indoor unit 3A shown in FIG.

As shown in FIG. 3 , the outdoor unit 2 has an outdoor unit controller 200 .
The outdoor unit control unit 200 includes an outdoor unit processor 210 that executes programs such as a CPU and MPU, and an outdoor unit storage unit 220 , and controls each unit of the outdoor unit 2 . The outdoor unit control unit 200 executes various processes through the cooperation of hardware and software such that the outdoor unit processor 210 reads out the control program 220A stored in the outdoor unit storage unit 220 and executes processing.

The outdoor unit storage unit 220 has a storage area for storing programs executed by the outdoor unit processor 210 and data processed by the outdoor unit processor 210 . The outdoor unit storage unit 220 stores a control program 220A executed by the outdoor unit processor 210 and other various data including setting data for performing various settings of the outdoor unit 2 . In addition, the outdoor unit storage unit 220 stores outdoor functional capacity information 220B indicating the capacity of the outdoor unit 2 (hereinafter referred to as "outdoor functional capacity"). The outdoor unit storage unit 220 has a nonvolatile storage area that stores programs and data in a nonvolatile manner. In addition, the outdoor unit storage unit 220 may include a volatile storage area and configure a work area for temporarily storing programs to be executed by the outdoor unit processor 210 and data to be processed.

The compressor 20 , the outdoor blower fan 24 , the outdoor air temperature sensor 41 , the low pressure sensor 28 , the high pressure sensor 29 , and the outdoor refrigerant temperature sensor 40 are connected to the outdoor unit control section 200 . The outdoor unit control unit 200 operates the compressor 20, the outdoor expansion valve 26, and the outdoor fan 24 based on the detection values of the outdoor air temperature sensor 41, the low pressure sensor 28, the high pressure sensor 29, and the outdoor refrigerant temperature sensor 40. Drive control.

The outdoor unit 2 includes an outdoor unit communication section 201 . The outdoor unit communication unit 201 is configured by communication hardware conforming to a predetermined communication standard, and communicates with each of the indoor units 3A, 3B, 3C, and 3D via the communication network 4 under the control of the outdoor unit control unit 200. .

The outdoor unit 2 has a notification unit 202 . The notification unit 202 has a configuration for displaying information, such as an LED, and notifies predetermined information. Note that the notification mode of the notification unit 202 is not limited to the display of information, and may be a mode of outputting sound or a mode of transmitting information to an external device.

As shown in FIG. 3 , the indoor unit 3A has an indoor unit controller 300 .
The indoor unit control unit 300 includes an indoor unit processor 310, which is a processor such as a CPU or MPU, which executes programs, and an indoor unit storage unit 320, and controls each unit of the indoor unit 3. The indoor unit controller 300 performs various processes through the cooperation of hardware and software such that the indoor unit processor 310 reads out the control program 320A stored in the indoor unit storage unit 320 and executes the process.

The indoor unit storage unit 320 has a storage area for storing a control program 320A executed by the indoor unit processor 310 and data processed by the indoor unit processor 310 . The indoor unit storage unit 320 stores a control program 320A executed by the indoor unit processor 310 and other various data including setting data 320B for performing various settings of the indoor unit 3 . In addition, the indoor unit storage unit 320 stores first indoor functional force control data 320C (control data), second indoor functional force control data 320D (control data), and third indoor functional force control data 320E (control data). Remember. These control data will be described later. The indoor unit storage unit 320 has a nonvolatile storage area that stores programs and data in a nonvolatile manner. In addition, the indoor unit storage unit 320 may include a volatile storage area and configure a work area for temporarily storing programs to be executed by the indoor unit processor 310 and data to be processed.

The indoor unit 3 of the present embodiment has a first capability, a second capability, and a third capability with different horsepowers as capabilities of the indoor unit 3 (hereinafter referred to as "indoor functional power"). The indoor unit 3 has one of the first capability, the second capability, and the third capability according to the control data read from the indoor unit storage unit 320 when the indoor unit control unit 300 operates the indoor unit 3. Driven by functional force.

The first indoor functional force control data 320C stored in the indoor unit storage unit 320 is control data for driving the indoor unit 3 with the indoor functional force indicating the first capability. The first ability is the indoor functional ability with the lowest horsepower among the second ability and the third ability, which will be described later.
The second indoor functional force control data 320D stored in the indoor unit storage unit 320 is control data for the indoor unit 3 to drive the indoor functional force indicating the second capability. The second ability is an indoor functional ability with higher horsepower than the first ability and lower horsepower than the third ability described later.
The third indoor functional force control data 320E stored in the indoor unit storage unit 320 is control data for driving the indoor unit 3 with the indoor functional force indicating the third capability. The third ability is an indoor functional ability with higher horsepower than the first ability and the second ability.

The indoor blower fan 30 , the indoor expansion valve 32 , and the indoor refrigerant temperature sensor 33 are connected to the indoor unit controller 300 . The indoor unit control unit 300 controls the opening degree of the indoor expansion valve 32, the indoor blower fan 30, and the flap 37 based on the drive control signal received from the remote control 5 via the remote control communication unit 302. is configured to

The indoor unit 3 has an indoor unit communication unit 301 . The indoor unit communication unit 301 is configured by communication hardware conforming to a predetermined communication standard, and communicates with each of the outdoor unit 2 and other indoor units 3 via the communication network 4 under the control of the indoor unit control unit 300. do.

The indoor unit 3 includes a remote control communication section 302 . The remote controller communication unit 302 includes communication hardware that communicates with the remote controller 5 according to a predetermined communication standard, and communicates with the remote controller 5 under the control of the indoor unit controller 300 .

Next, the operation of the air conditioning system 1 of this embodiment will be described.
FIG. 4 is a flow chart showing the operation of the outdoor unit 2 and the indoor unit 3 related to the setting of the indoor functional power. In FIG. 4, a flowchart FA is a flowchart showing the operation of the indoor unit 3, and a flowchart FB is a flowchart showing the operation of the outdoor unit 2. As shown in FIG. Each of the indoor units 3A, 3B, 3C, and 3D performs the operation of the indoor unit 3 shown in FIG.

Referring to the flowchart FA, the indoor unit controller 300 of the indoor unit 3 determines whether or not to start setting the indoor functional power (step SA1). For example, when the indoor unit control unit 300 determines that the indoor unit 3 is powered on for the first time, it makes an affirmative determination in step SA1.

When the indoor unit control unit 300 determines to start setting the indoor functional power (step SA1: YES), it refers to the setting data 320B to determine whether the setting is made to automatically set the indoor functional power. is determined (step SA2). For example, it is assumed that the setting data 320B at the time of power-on for the first time describes data indicating that the setting for automatically setting the indoor functional power is ON. In this case, the indoor unit control section 300 makes an affirmative determination in step SA2 at the first step SA2 after the power is turned on for the first time.

When the indoor unit control section 300 makes an affirmative determination in step SA2, the indoor unit communication section 301 transmits a request command requesting transmission of the outdoor function information 220B to the outdoor unit 2 (step SA3). In step SA3, if an address used for communication is not assigned to each of the devices connected to the communication network 4, the request command is sent to the other indoor units 3 connected to the communication network 4 in addition to the outdoor unit 2. is also sent. However, since the request command is a command that can be processed only by the outdoor unit 2, only the outdoor unit 2 responds to the request command.

Referring to the flowchart FB, the outdoor unit controller 200 receives the request command through the outdoor unit communication unit 201 (step SB1).

Next, the outdoor unit control unit 200 reads the outdoor functional force information 220B from the outdoor unit storage unit 220 based on the received request command, and transmits the outdoor functional force information 220B as a response to the request command to the indoor unit through the outdoor unit communication unit 201. 3 (step SB3). In step SB3, if an address is not assigned to each of the devices connected to the communication network 4, the response to the request command will be the indoor unit 3 that transmitted the request command and other indoor units connected to the communication network 4. It is also sent to machine 3.

Referring to flowchart FA, indoor unit control unit 300 receives outdoor functional force information 220B through indoor unit communication unit 301 (step SA4).

Next, the indoor unit control unit 300 transmits a detection command for detecting the number of indoor units 3 connected to the outdoor unit 2 via the communication network 4 to all other indoor units 3 through the indoor unit communication unit 301. (step SA5). In step SA5, if no address is assigned to each device connected to the communication network 4, the detection command is also sent to the outdoor unit 2 connected to the communication network 4. FIG. However, since the detection command is a command that can be processed only by the indoor unit 3 , there is no response to the detection command from the outdoor unit 2 .

Next, the indoor unit controller 300 receives a response to the detection command from another indoor unit 3 through the indoor unit communication unit 301 (step SA6).

Next, the indoor unit control section 300 detects the number obtained by adding 1 to the number of responses to the detection command received in step SA5 as the number of indoor units 3 connected to the outdoor unit 2 (step SA7).

Next, the indoor unit control unit 300 divides the outdoor functional force indicated by the outdoor functional force information 220B received in step SA4 by the number of indoor units 3 connected to the outdoor unit 2 detected in step SA6 (step SA8). .

Next, the indoor unit control section 300 determines whether or not the divided outdoor function force is within the capacity determination range (step SA9).

Here, step SA9 will be described in detail.
The capacity determination range is set for the outdoor functional force obtained by the division in step SA8 in order to determine the indoor functional force to be set in the indoor unit 3 based on the outdoor functional force obtained by the division in step SA8. range. The capacity determination range is provided with different upper and lower limits for each of the plurality of capacities of the indoor unit 3 . The ability determination range is appropriately determined by preliminary tests, simulations, or the like, and is stored in the indoor unit storage section 320 as information.
In this embodiment, the indoor unit 3 has three indoor functional powers, ie, a first power, a second power, and a third power. Therefore, the indoor unit storage unit 320 stores three capacity determination ranges as information: a capacity decision range corresponding to the first capacity, a capacity decision range corresponding to the second capacity, and a capacity decision range corresponding to the third capacity. . The upper limit of the ability determination range corresponding to the first ability is set smaller than the lower limit of the ability determination range corresponding to the second ability, and the upper limit of the ability determination range corresponding to the second ability corresponds to the third ability. It is set smaller than the lower limit of the capacity determination range.

The ability determination range and the upper and lower limits of the ability determination range are determined from the following viewpoints.
The upper and lower limits of the capacity determination range corresponding to the first capacity are the first capacity, the second capacity, the outdoor functional power obtained by division when included in the capacity decision range corresponding to the first capacity, and the third ability are appropriately determined to be closest to the first ability. In addition, the capacity determination range corresponding to the first ability is appropriately set as a range such that the outdoor functional power obtained by division when it is included in the capacity determination range corresponding to the first ability can be approximated as the first ability. It is defined.
In addition, the upper limit and lower limit of the capacity determination range corresponding to the second capacity, the outdoor functional power obtained by division in the case of being included in the capacity decision range corresponding to the second capacity, the first capacity, the second It is appropriately determined to be closest to the second ability among the ability and the third ability. In addition, the capacity determination range corresponding to the second ability is appropriately set as a range such that the outdoor functional power obtained by division when it is included in the capacity determination range corresponding to the second ability can be approximated as the second ability. It is defined.
In addition, the upper limit and lower limit of the capacity determination range corresponding to the third capacity, the outdoor functional power obtained by division when included in the capacity determination range corresponding to the third capacity, the first capacity, the second It is appropriately determined to be closest to the third ability among the ability and the third ability. In addition, the capacity determination range corresponding to the 3rd capacity is appropriately defined as a range in which the outdoor functional power obtained by division when it is included in the capacity determination range corresponding to the 3rd capacity can be approximated as the 3rd capacity. It is

The indoor unit control unit 300 determines whether the outdoor functional force obtained by the division in step SA8 is a capacity determination range corresponding to the first capacity, a capacity decision range corresponding to the second capacity, and a capacity decision range corresponding to the third capacity. If it is not within any of the capability determination ranges, a negative determination is made in step SA9. On the other hand, the outdoor functional force obtained by the division in step SA8 is one of the ability determining range corresponding to the first ability, the ability determining range corresponding to the second ability, and the ability determining range corresponding to the third ability. If it is within the determination range, an affirmative determination is made in step SA9.

If a negative determination is made in step SA9, the indoor unit control section 300 executes corresponding processing (step SA16). The corresponding process is, for example, a process of notifying the remote controller display unit 52 of the remote controller 5 of a warning indicating that the setting of the indoor functional power cannot be executed. Further, for example, when an address is assigned to each device connected to the communication network 4, the indoor unit control unit 300, as a corresponding process, transmits the information to the outdoor unit 2 and sends it to the notification unit 202 of the outdoor unit 2. Let the information be notified.

On the other hand, if the indoor unit control unit 300 makes an affirmative determination in step SA9, the indoor functional force is determined to be the capability corresponding to the ability determination range including the outdoor functional force obtained by the division in step SA8 (step SA10). . When the outdoor functional force obtained by the division in step SA8 is within the capability determination range corresponding to the first capability, the indoor unit control unit 300 determines the indoor functional force to be set in the indoor unit 3 as the first capability. . Similarly, the indoor unit control unit 300 determines the indoor functional force to be set as the second capability when the outdoor functional force obtained in step SA8 is within the capability determination range for the second capability, and determines the indoor functional force to be set as the second capability. The outdoor functional power to be set when it is within the capacity determination range is determined as the third capacity. In this manner, the indoor unit control unit 300 determines the outdoor functional power set for each indoor unit 3 to be a smaller horsepower as the number of detected indoor units 3 increases. In other words, the smaller the number of detected indoor units 3, the indoor unit control unit 300 determines the outdoor functional power set for each indoor unit 3 to have a larger horsepower.

Next, the indoor unit control unit 300 sets the determined indoor functional power by setting the setting data 320B so that the control data corresponding to the determined indoor functional power is read when the indoor unit 3 is driven (step SA11). .

Next, the indoor unit control unit 300 turns off the setting for automatically setting the indoor functional power (step SA12). Then, the indoor unit control section 300 returns the process to step SA2.

Returning to the description of step SA2, when the indoor unit control unit 300 refers to the setting data 320B and determines that it is not set to automatically set the indoor functional power (step SA2: NO), the outdoor unit 2 start monitoring whether or not all the indoor units 3 connected to 2 have completed the setting of the indoor functional power (step SA13).

Next, after starting monitoring, the indoor unit control section 300 determines whether or not all the indoor units 3 connected to the outdoor unit 2 have completed the setting of the indoor functional power (step SA14).

For example, the indoor unit control unit 300 transmits information indicating that the indoor functional force is completed to the other indoor units 3 through the indoor unit communication unit 301 when the setting of the indoor functional force is completed. In this case, the indoor unit control unit 300 determines whether all the indoor units 3 connected to the outdoor unit 2 have completed the setting of the indoor functional power, depending on whether or not the indoor unit communication unit 301 has received the three pieces of information. determine whether

When the indoor unit control unit 300 determines that all the indoor units 3 connected to the outdoor unit 2 have not completed the setting of the indoor functional power (step SA14: NO), after starting the monitoring in step SA13, the predetermined It is determined whether or not the period has elapsed (step SA15).

When the indoor unit control unit 300 determines that the predetermined period has not elapsed since the monitoring was started in step SA13 (step SA15: NO), the process returns to step SA14.

On the other hand, when the indoor unit control section 300 determines that the predetermined period has passed since the monitoring in step SA13 was started (step SA15: YES), it executes the process of step SA16. The corresponding process here is, for example, a process of notifying the remote controller or the outdoor unit 2 of a warning indicating that the setting of the indoor functional power has not been completed for all the indoor units 3 connected to the outdoor unit 2. .

Returning to the description of step SA14, when the indoor unit control unit 300 determines that all the indoor units 3 connected to the outdoor unit 2 have completed the setting of the indoor functional power (step SA14: YES), automatic address setting is started. Information indicating the request is transmitted to the outdoor unit 2 by the indoor unit communication unit 301 (step SA17). Automatic address setting means automatically setting an address to each of the outdoor unit 2 and the plurality of indoor units 3 connected to the communication network 4 in the air conditioning system 1 .

Note that if the address has already been assigned, the indoor unit 3 may skip step SA17 and step SA18 described later.

With reference to the flowchart FB, the outdoor unit control unit 200 of the outdoor unit 2 determines whether information indicating a request to start automatic address setting has been received from the indoor unit 3 connected to the communication network 4 (step SB3 ). The indoor units 3 are configured to request the start of automatic address setting when all the indoor units 3 connected to the outdoor unit 2 have completed the setting of the indoor functional capacity. Therefore, the outdoor unit 2 does not make an affirmative determination in step SB3 unless all of the connected indoor units 3 have completed the setting of the indoor functional power.

When the determination in step SB3 is affirmative, the outdoor unit control section 200 executes automatic address setting (step SB4). The outdoor unit control unit 200 assigns addresses to the outdoor unit 2 and all the indoor units 3 in the process of step SB4.

Referring to the flowchart FA, the indoor unit controller 300 of the indoor unit 3 executes automatic address setting together with the outdoor unit 2 (step SA18). The indoor unit control section 300 writes the address assigned to the outdoor unit 2 and the address assigned to the outdoor unit 2 in the setting data 320B in the automatic address setting of step SA18.

As a result, devices connected to the communication network 4 are assigned new or changed addresses.

Note that the outdoor unit control section 200 may skip the processing of steps SB3 and SB4 when addresses are already assigned to all devices connected to the communication network 4 before step SB3 is executed.

Referring to the flowchart FB, the outdoor unit control unit 200 transmits information indicating the set indoor functional power from all the indoor units 3 connected to the outdoor unit 2 based on the address assigned to each indoor unit 3. A request is made (step SB5).

Referring to the flowchart FA, the indoor unit control unit 300 of the indoor unit 3 transmits the information indicating the indoor functional power set in step SA11 through the indoor unit communication unit 301 based on the transmission request from the outdoor unit 2 ( Step SA19).

Referring to the flowchart FB, the outdoor unit controller 200 of the outdoor unit 2 receives the information indicating the indoor functional capacity from all the indoor units 3 through the outdoor unit communication unit 201 (step SB6).

Next, the outdoor unit control unit 200 determines that the total indoor functional power acquired from all the indoor units 3 connected to the outdoor unit 2 is within the allowable range of the capability indicated by the outdoor functional power information 220B stored in the outdoor unit storage unit 220. (step SB7).

When the outdoor unit control unit 200 makes a negative determination in step SB7, the notification unit 202 issues a warning (step SB8).

On the other hand, if the determination at step SB7 is affirmative, the outdoor unit control unit 200 determines that the indoor functional power settings for all the indoor units 3 connected to the outdoor unit 2 have been normally performed (step SB9), and performs this process. exit.

In the operation of the outdoor unit 2 and the indoor unit 3 described above, the automatic address setting is executed after the indoor unit 3 completes the setting of the indoor functional power. It may be before sending the command.

Next, the overall operation of the air conditioning system 1 when the indoor unit 3 and the outdoor unit 2 perform the operations shown in FIG. 4 will be described.
FIG. 5 is a sequence diagram showing the operation of the air conditioning system 1. As shown in FIG.
In the description of the air conditioning system 1 with reference to FIG. 5, it is assumed that the indoor units 3A, 3B, 3C, and 3D have normally completed the setting of the indoor functional power. It is also assumed that addresses in the communication network 4 are not assigned to each device at the start of the sequence.

As shown in FIG. 5, the indoor unit 3A transmits a request command to the outdoor unit 2 when the indoor unit 3A starts to set the indoor functional power by power-on or the like (step S10). The indoor units 3B, 3C, and 3D similarly transmit request commands to the outdoor unit 2 (steps S220, S30, S40).

When the request command is received from the indoor unit 3A, the outdoor unit 2 transmits the outdoor functional force information 220B to the indoor unit 3A (step S50). Similarly, when the outdoor unit 2 receives the request command from each of the indoor units 3B, 3C, and 3D, it transmits the outdoor functional power information 220B to each of the indoor units 3 (steps S51, S52, S53).

Although FIG. 5 shows that the request commands are transmitted in the order of the indoor units 3A, 3B, 3C, and 3D, the timing at which the request commands are transmitted in the air conditioning system 1 is in this order. They are not always there, they may be at the same time or in another order. Also, the order in which the outdoor unit 2 transmits responses to the request commands is not necessarily the order shown in FIG.

The indoor unit 3A receives the outdoor functional capacity information 220B from the outdoor unit 2 (step S11). Similarly, the indoor units 3B, 3C, and 3D receive the outdoor functional force information 220B from the outdoor unit 2 (steps S21, S31, S41).

When the indoor unit 3A receives the outdoor function force information 220B from the outdoor unit 2, it transmits a detection command to each of the indoor units 3B, 3C, and 3D, and receives a response to the detection command from each of the indoor units 3B, 3C, and 3D. (step S11). Similarly, the indoor unit 3B operates with respect to the indoor units 3A, 3C, and 3D (step S21), the indoor unit 3C operates with respect to the indoor units 3A, 3B, and 3D (step S31), and the indoor unit 3D operates on the indoor units 3A, 3B, and 3C (step S41).

As for the execution order of steps S11, S21, S31, and S41, the timing of transmitting the detection command and receiving the response to the detection command is not necessarily the order shown in FIG.

When the indoor unit 3A receives responses to the detection commands from the indoor units 3B, 3C, and 3D, it detects the number of the indoor units 3 connected to the outdoor unit 2 (step S12). Similarly, each of the indoor units 3B, 3C, 3D detects the number of indoor units 3 connected to the outdoor unit 2 (steps S22, S32, S33). After receiving the response to the detection command, each indoor unit 3 detects the number of indoor units 3 at appropriate timing.

When detecting the number of indoor units 3 connected to the outdoor unit 2, the indoor unit 3A sets the indoor functional power (step S13). Similarly, each of the indoor units 3B, 3C, and 3D sets the outdoor functional power (steps S24, S34, and S44).

Then, the indoor units 3A, 3B, 3C, 3D and the outdoor unit 2 perform automatic address setting (step S60).

[Modification]
Next, a modified example will be described.
The air conditioning system 1 according to the above-described embodiment is configured such that all the indoor units 3 connected to the outdoor unit 2 transmit request commands to the outdoor unit 2 and receive the outdoor functional force information 220B from the outdoor unit 2 . In the air conditioning system 1 according to the modification, one indoor unit 3 receives the outdoor function force information 220B from the outdoor unit 2, and the other indoor unit 3 receives the outdoor function force information 220B from the indoor unit 3. Receive force information 220B.

The operation of the air conditioning system 1 according to the modification will be described.
In the description of the operation of the air conditioning system 1 according to the modified example, it is assumed that an address of the communication network 4 is assigned to each of the outdoor unit 2 and the indoor units 3A, 3B, 3C, and 3D.
When the indoor functional power setting trigger occurs, the indoor unit 3 transmits the outdoor functional power information 220B to the indoor unit 3A. The indoor unit 3A receives the outdoor functional capacity information 220B. Next, each of the indoor units 3B, 3C, and 3D transmits a command requesting transmission of the outdoor function information 220B to the indoor unit 3A. The indoor unit 3A transmits the outdoor functional force information 220B to the indoor units 3B, 3C, and 3D as a response to the command. Each indoor unit 3 sets the indoor functional power. The indoor unit 3B may receive the outdoor functional force information 220B from the outdoor unit 2, the indoor unit 3C may receive the outdoor functional force information 220B from the outdoor unit 2, and the indoor unit 3D may receive the outdoor unit 2, the outdoor function information 220B may be received.

Another operation of the air conditioning system 1 according to the modification will be described.
In this explanation, it is assumed that the indoor unit 3C is replaced with the indoor unit 3C'. Also, in this description, addresses are assigned to the indoor units 3A, 3B, and 3D, but no address is assigned to the indoor unit 3C'.
In this case, the outdoor unit 2 transmits the outdoor functional capacity information 220B to any one of the indoor units 3A, 3B, and 3D to which the address is assigned. Then, each indoor unit 3 that has not received the outdoor functional force information 220B including the indoor unit 3C' acquires the outdoor functional force information 220B from the indoor unit 3 that has received the outdoor functional force information 220B. The indoor unit 3C′ acquires the outdoor functional force information 220B by transmitting a command requesting transmission of the outdoor functional force information 220B to all the indoor units 3 connected to the communication network 4 . Then, the air-conditioning system 1 sets the indoor functional capacity, and since no address is assigned to the newly installed indoor unit 3C', automatic address setting is performed.

As described above, the air conditioning system 1 includes the outdoor unit 2 and a plurality of indoor units 3 connected to the outdoor unit 2 . The indoor unit 3 includes an indoor unit controller 300 and an indoor unit communication unit 301 . The indoor unit control unit 300 receives the outdoor functional capacity information 220B indicating the capacity of the outdoor unit 2 from the outdoor unit 2 via the indoor unit communication unit 301, detects the number of indoor units 3 provided in the air conditioning system 1, Based on the number of detected indoor units 3 and the outdoor functional force indicated by the received outdoor functional force information 220B, the indoor functional force is determined according to the number of detected indoor units 3, and the determined indoor functional force is set. do.

Further, in the control method of the air conditioning system 1, the indoor unit 3 receives the outdoor functional force information 220B indicating the outdoor functional force from the outdoor unit 2, detects the number of the indoor units 3 included in the air conditioning system 1, and detects Based on the number of indoor units 3 detected and the outdoor functional force indicated by the received outdoor functional force information 220B, the indoor functional force corresponding to the number of detected indoor units 3 is determined, and the determined indoor functional force is set. .

According to the air conditioning system 1 having this configuration and the control method of the air conditioning system 1, each indoor unit 3 connected to the outdoor unit 2 has an indoor function according to the number of connections of the indoor units 3 connected to the outdoor unit 2. Since the force is set, even when a plurality of indoor units 3 are connected to the outdoor unit 2, each indoor unit 3 can set an appropriate indoor function force.

Further, the indoor unit control unit 300 divides the outdoor functional force indicated by the received outdoor functional force information 220B by the number of detected indoor units 3, and determines the indoor functional force based on the outdoor functional force obtained by dividing.

According to this, each of the indoor units 3 has an indoor functional force corresponding to the number of indoor units 3 connected to the outdoor unit 2 with respect to the outdoor functional force, and has the same indoor function as the other indoor units 3 power can be set. Therefore, each indoor unit 3 can set the indoor functional power so that the total indoor functional power set by each indoor unit 3 is within the allowable range of the outdoor functional power.

The indoor unit control unit 300 monitors for a predetermined period whether or not all the indoor units 3 included in the air conditioning system 1 have completed the setting of the indoor functional power.

In this embodiment, when all the indoor units 3 complete the setting of the indoor functional power, the automatic address setting is performed together with the outdoor unit 2 . In automatic address setting, the outdoor unit 2 is the master and each indoor unit 3 is the slave. Therefore, each indoor unit 3 is placed under the control of the outdoor unit 2 at the time of automatic address setting. Therefore, even if the indoor unit 3 is executing the setting of the indoor function capacity, the capacity setting is interrupted and the automatic address setting is performed. will be executed. The setting of the indoor functional force is not always completed at the same timing for all the indoor units 3, and a time lag may occur in each indoor unit 3. Therefore, for example, in a configuration in which the automatic address is set when the setting of the indoor functional power is completed for some of all the indoor units 3, there is a possibility that all the indoor units 3 cannot complete the setting of the indoor functional power. Therefore, each indoor unit 3 monitors whether or not all the indoor units 3 have completed the setting of the indoor functional power for a predetermined period. As a result, each indoor unit 3 can be prevented from executing other processes after setting the capacity until the capacity setting of all the indoor units 3 is completed for a predetermined period. Therefore, the air conditioning system 1 can set the indoor functional power of all the indoor units 3 connected to the outdoor unit 2 even when a time lag occurs in setting the capacity of each indoor unit 3 .

In addition, the indoor unit 3 includes an indoor unit storage unit 320 that stores control data for each of indoor functional powers with different horsepowers.

According to this, the indoor unit 3 stores the control data for each of the plurality of indoor functional capabilities that the indoor unit 3 has, so that the number of models of the indoor unit 3 can be determined, for example, by the number of capabilities of the indoor unit 3 and the number of indoor units 3 It is not necessary to multiply the number by the number of different types of housings, and only the number of different types of housings of the indoor unit 3 can be used. Therefore, an increase in the number of models of the indoor units 3 can be suppressed. In addition, since an increase in the number of models of the indoor units 3 can be suppressed, predetermined management of the indoor units 3 such as inventory management becomes easier.

Also, the indoor unit control unit 300 receives the outdoor function power information 220B from the outdoor unit 2 through the indoor unit communication unit 301 .

According to this, even if each indoor unit 3 receives the outdoor functional force information 220B from the outdoor unit 2, each indoor unit 3 can set an appropriate indoor functional force.

Also, the indoor unit control unit 300 of the indoor unit 3 of 1 receives the outdoor functional power information 220B from the outdoor unit 2 through the indoor unit communication unit 301 . The indoor unit controller 300 of another indoor unit 3 different from the one indoor unit 3 receives the outdoor functional force information 220B from the one indoor unit 3 through the indoor unit communication unit 301 .

According to this, one indoor unit 3 receives the outdoor functional force information 220B from the outdoor unit 2, and another indoor unit 3 different from the one indoor unit 3 receives the outdoor functional force information 220B from the one indoor unit 3. , each indoor unit 3 can set an appropriate indoor functional power.

The outdoor unit 2 also includes an outdoor unit control unit 200 , an outdoor unit communication unit 201 , and a notification unit 202 . The outdoor unit control unit 200 acquires the indoor functional powers set from all the indoor units 3 by the outdoor unit communication unit 201, and when the total of the acquired indoor functional powers is outside the allowable range of the outdoor functional powers, notification A warning is generated by the unit 202 .

According to this, since the user who sets the indoor unit 3 can recognize that the total of the indoor functional power set by each indoor unit 3 is outside the allowable range of the outdoor functional power, the capacity of the indoor unit 3 Can assist users in setting up.

The above-described embodiments and modifications merely show one aspect of the present invention, and can be arbitrarily modified and applied within the scope of the present invention.

For example, the number of indoor functional powers that the indoor unit 3 has is not limited to three, and may be more or less as long as it is plural. In addition, the indoor unit 3 stores control data corresponding to the indoor functional power as many as the number of indoor functional powers.

Also, for example, the number of indoor units 3 connected to the outdoor unit 2 is not limited to four, and may be more or less as long as it is plural.

Further, for example, the configuration may be such that the setting of the indoor functional power is started by operating the remote controller 5 . For example, if the air conditioning system 1 has a configuration in which the outdoor unit 2 and all the indoor units 3 included in the air conditioning system 1 can be restarted by operating a remote controller 5, the indoor unit can be restarted by operating the remote controller. Start setting the functional power. As a result, at least all of the indoor units 3 can be brought into the flow shown in FIG.

Also, the functions of the outdoor unit control section 200 and the indoor unit control section 300 may be realized by a plurality of processors or semiconductor chips.

Moreover, each part shown in FIG. 3 is an example, and a specific implementation form is not particularly limited. That is, it is not always necessary to mount hardware corresponding to each part individually, and it is of course possible to adopt a configuration in which one processor executes a program to realize the function of each part. Also, part of the functions implemented by software in the above-described embodiments may be implemented by hardware, or part of the functions implemented by hardware may be implemented by software. In addition, specific detailed configurations of other parts of the outdoor unit 2 and the indoor unit 3 can be arbitrarily changed without departing from the scope of the present invention.

Further, for example, the step unit of the operation shown in FIG. The present invention is not limited by the division method or name of the unit. It may be divided into more steps depending on the processing contents. Also, one step unit may be divided to include more processes. Also, the order of the steps may be changed as appropriate within the scope of the present invention.

INDUSTRIAL APPLICABILITY As described above, the air conditioning system and the method for controlling the air conditioning system according to the present invention can be used for setting the capacity of the indoor units of a plurality of indoor units connected to the outdoor unit.

1 air conditioning system 2 outdoor unit 3, 3A, 3B, 3C, 3D indoor unit 200 outdoor unit control unit 201 outdoor unit communication unit 202 reporting unit 220 outdoor unit storage unit 220B outdoor functional power information 300 indoor unit control unit 301 indoor unit communication Part 320 Indoor unit storage part 320C First indoor function force control data (control data)
320D Second indoor function force control data (control data)
320E Third indoor function power control data (control data)

Claims (8)

In an air conditioning system comprising an outdoor unit and a plurality of indoor units connected to the outdoor unit,
The indoor unit includes an indoor unit control unit and an indoor unit communication unit,
The indoor unit control unit
receiving outdoor functional capacity information indicating the capacity of the outdoor unit from the outdoor unit via the indoor unit communication unit;
detecting the number of indoor units included in the air conditioning system;
determining the capacity of the indoor unit according to the number of the detected indoor units based on the number of the detected indoor units and the capacity of the outdoor unit indicated by the received outdoor functional capacity information;
setting the determined capacity of the indoor unit;
An air conditioning system characterized by: The indoor unit control unit
dividing the capacity of the outdoor unit indicated by the received outdoor functional capacity information by the number of the detected indoor units, and determining the capacity of the indoor unit based on the capacity of the outdoor unit obtained by dividing;
The air conditioning system according to claim 1, characterized by: The indoor unit control unit
monitoring for a predetermined period whether or not all the indoor units included in the air conditioning system have completed setting the capabilities of the indoor units;
The air conditioning system according to claim 1 or 2, characterized by: The indoor unit
An indoor unit storage unit that stores control data corresponding to the capabilities of the indoor unit for each of a plurality of capabilities of the indoor unit,
The air conditioning system according to any one of claims 1 to 3, characterized by: The indoor unit control unit
receiving the outdoor function information from the outdoor unit by the indoor unit communication unit;
The air conditioning system according to any one of claims 1 to 4, characterized in that: The indoor unit control unit of the indoor unit of 1,
receiving the outdoor function information from the outdoor unit by the indoor unit communication unit;
The indoor unit control unit of the other indoor unit different from the one indoor unit,
receiving the outdoor functional power information from the one indoor unit by the indoor unit communication unit;
The air conditioning system according to any one of claims 1 to 4, characterized in that: The outdoor unit includes an outdoor unit control unit, an outdoor unit communication unit, and a notification unit,
The outdoor unit control unit acquires the capabilities of the indoor units set from all the indoor units by the outdoor unit communication unit, and the total of the acquired capabilities of the indoor units is the allowable range of the capabilities of the outdoor units. When outside, the notification unit notifies a warning,
The air conditioning system according to any one of claims 1 to 6, characterized in that: In a control method for an air conditioning system comprising an outdoor unit and a plurality of indoor units connected to the outdoor unit,
The indoor unit
receiving outdoor functional capacity information indicating the capacity of the outdoor unit from the outdoor unit;
detecting the number of indoor units included in the air conditioning system;
determining the capacity of the indoor unit according to the number of the detected indoor units based on the number of the detected indoor units and the capacity of the outdoor unit indicated by the received outdoor functional capacity information;
setting the determined capacity of the indoor unit;
A control method for an air conditioning system, characterized by:

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